Caldera forming eruption has a huge influence on human society and it is important to reveal the sequence of magma ascent process during the eruption. Approximately 7.6 ka, caldera-forming activity of Mashu Volcano started as phreatomagmatic eruption (Ma-j) and followed Plinian falls (Ma-i, -h, -g) and pyroclastic flow (Ma-f). In this study, we performed the textural and synchrotron analyses for the pumice from Mashu caldera-forming activity and discuss the magma ascent and oxidation processes during the caldera-forming eruption.
We conducted the textural and synchrotron analyses for Mashu caldera-forming eruption. We sieved the samples and picked up the pumices larger than 2φ. Samples were washed by a sonic wave washer and dried at 110℃. Powdered pumices were used for the synchrotron analysis. To determine the Fe³⁺/Fe²⁺ ratio, we collected the absorption spectra between 650 [eV] and 750 [eV] with using the standard materials at room temperature using the BL-10 beamline at the New SUBARU, Laboratory of Advanced Science and Technology for Industry, University of Hyogo, Japan. The soft X-rays were focused on 2.5 mm × 1.2 mm area. In the Ma-i layer, Fe³⁺/Fe²⁺ changes from 11.5 to 16.6 from lower to the upper Ma-i pumice. On the other hand, Fe³⁺/Fe²⁺ in Ma-h layer changes from 9.2 to 13.1. Furthermore, we analyzed the vesicle texture by EPMA and estimate the magma ascent rate. We discuss the magma ascent and oxidation process of caldera-forming eruption based on the textural and synchrotron analyses for the Ma pumices.